JP6841583B2 - Engine control unit configuration security - Google Patents

Description

The present disclosure relates to engine control units that generally control an engine, and in particular to methods and systems for protecting the configuration of an engine control system.

All modern types of engines are complex machines that require precise calibration of many parameters to operate with optimum performance and efficiency. Therefore, many engine manufacturers set such calibrations at the time of manufacture, associating "molds" with calibrations, and further associating "molds" with engine control units that control the engine. In that case, these molds can be used to ensure that only calibrations with the same mold as the engine control unit or a mold compatible with the engine control unit will be performed on the unit. The engine manufacturer may not allow the end user to adjust the calibration at all, instead leaving any changes pre-made or approved by the manufacturer and the engine properly calibrated. Require that it be ensured that it is within the operating specifications.

In an exemplary, non-limiting embodiment, the system has memory with instructions and, when executing instructions, the serial number associated with the engine control unit and the memory receiving the requested engine control unit changes. It can be equipped with a processor to be connected. The system determines that the requested engine control unit change has been approved and generates a code containing the serial number associated with the engine control unit and the instruction to cause the engine control unit to perform the requested engine control unit change. can do.

In another exemplary, non-limiting embodiment, the calibration change device discloses a serial number associated with an engine control unit and a method for receiving the requested engine control unit change. The method further determines that the requested engine control unit change has been approved and provides a code with a serial number associated with the engine control unit and an instruction to cause the engine control unit to perform the requested engine control unit change. Generate.

In another exemplary, non-limiting embodiment, when executed by a processor, computer readable media receives the processor the serial number associated with the engine control unit and the requested engine control unit change. It is possible to have a computer-executable instruction that executes an operation such as. This operation further includes a code that determines that the requested engine control unit change has been approved, a serial number associated with the engine control unit, and an instruction that causes the engine control unit to perform the requested engine control unit change. Can include producing.

The above overview and the following detailed description will be better understood by reading with the drawings. For the purposes of showing the subject matter of the claimed invention, examples showing various embodiments are shown in the figure, but the invention is not limited to the particular systems and methods disclosed.

These and other features, aspects, and advantages of the subject matter of the present invention will be better understood by reading the following detailed description with reference to the accompanying drawings.

FIG. 6 is a block diagram of a non-limiting exemplary engine control unit configuration security system. It is a flowchart which shows the method of realizing the non-limiting exemplary engine control unit configuration security system. It is a flowchart which shows the method of realizing the non-limiting exemplary engine control unit configuration security system. FIG. 6 is a block diagram of a non-limiting exemplary engine control unit configuration security system. It is a flowchart which shows the method of realizing the non-limiting exemplary engine control unit configuration security system. It is a flowchart which shows the method of realizing the non-limiting exemplary engine control unit configuration security system. It is an exemplary block diagram representing a general purpose computer system that can incorporate aspects of the methods and systems disclosed herein.

FIG. 1 shows an exemplary system 100 that can be implemented by one embodiment. The illustrated system 100 is a simplified block diagram used to illustrate the concepts disclosed herein and is therefore any physical requirement for any embodiment disclosed herein. It should not be construed as describing a requirement or specific configuration. All components, devices, systems, and methods disclosed herein can be implemented in any number of components of any shape, form, or type, making it possible to implement the disclosed embodiments. Any combination of any such components is intended to be within the scope of this disclosure.

The engine 110 can be of any type of engine and includes any type of internal combustion engine, such as a gas turbine engine, a diesel engine, and a gasoline engine. The engine control unit 120 can be any type of computing device or controller, can control any component of the engine 110 and the engine 110, and controls parameters that affect the operation of the engine 110 and /. Or can be set. Modern engines can have many different parameters and calibrations that can be adjusted or set. These include maximum horsepower possible, maximum torque possible, maximum revolutions per minute (RPM) possible, maximum overload, time map, speed control adjustment, maximum boost to enable turbocharged engine, engine, There are engine calibration factors, as well as limits to engine fluid temperature, detonation limits, and the number of cylinders to use under certain conditions. All such parameters and calibrations, and any other parameters and calibrations that can be configured for the engine, are intended to be within the scope of the present disclosure. All parameters and calibrations can be initially set at the time of manufacture or before the engines using such engine control units are provided to the customer to ensure they are accurate. ..

The "type" can be configured in the engine control unit 120 and is associated with each calibration and parameter configured in the engine to ensure that the engine is not configured with incompatible calibrations or parameters. be able to. For example, the mold can be an engine with a particular mechanical configuration (eg, a 6-cylinder diesel engine that produces 500 horsepower). By checking that any calibration or parameter was associated with the same type, the engine control unit is incompatible with the engine (eg, calibration for a 12-cylinder engine or a petrol engine) or an unacceptable change (for example). For example, it can be ensured that the horsepower will not be increased to 600 without paying an additional fee. The engine control unit will not allow the customer to change such parameters and calibration until the type associated with the new parameters and calibration matches the type of engine configured within the engine control unit. Can be configured. Changing the type configured within the engine control unit may require assistance from the seller or manufacturer of the engine and / or engine control unit. The engine control unit 120 can first consist of many or all possible parameters and calibrations, but only presents them for the operations associated with the type specified in the engine control unit. However, please note that it is okay. When changing types, the operator may then be allowed to adjust the parameters and calibrations associated with the new type.

The engine control unit 120 can be configured with a mold 121, which acts as an indicator of the type assigned to this engine and can be used to verify that the parameters and calibration changes have the same type. The engine control unit 120 may also have a serial number. The engine control unit may also be configured with an interface 122 that allows bidirectional processing with the engine control unit 120. Interface 122 includes any one or more such as keyboards, monitors, mice, disk drives, and network connections to any one or more networks (including the Internet, other data networks, and voice networks). It may be.

If it is determined that the type change is necessary, the operator of the engine 110 can send a request 160 requesting the type change code and adjust the type composed of the engine control unit 120. The request 160 can take any form, including a call in which the operator requests a remodeling code from the seller or manufacturer of the engine 110. Accordingly, the seller or manufacturer may generate and provide such code as described herein. Alternatively, the engine 110 operator can use an automated interface, such as a web page, to generate request 160, and in some embodiments, automatically generated, generated as described herein. You can receive the type change code. In yet another embodiment, the operator emails or sends some other form of electronic request 160 for such code to the manufacturer or seller of engine 110 over the Internet 150. And can receive a response in the same way, including the required type change code that can be generated manually or automatically. All such embodiments are intended to be within the scope of this disclosure.

In one embodiment, the request 160 from the operator can include the desired particular type change identifier 162 and the serial number 161 of the engine control unit 120. Alternatively, instead of the serial number of the engine control unit 120, the request comprises one or more identifiers that can be used by the manufacturer or seller of the engine 110 to determine the serial number for the engine control unit 120. But it may be. In that case, this request may be made to the manufacturer or seller of the engine 110. Note that the request is also encrypted so that only the intended recipient can decrypt the request.

Upon receipt of the request, the manufacturer or seller of the engine 110 can validate the request, decrypt the request 160 if necessary, and generate the retype code 140. In some embodiments, this process may be automated. The validation process is entitled to determine if the requested type is actually compatible with the engine 110 and / or the operator of the engine 110 is entitled to a change to the requested type (eg, payment). It may include determining that. In one embodiment, the code generation server 130 may be used to generate such code. The code generation server 130 can be any type of computing device or any combination of any number and type of computing device. The code generation server 130 can be configured with a database 132, which can be a database configured with a serial number, the current configuration type, and any other data associated with the engine and engine control unit. Alternatively, it can be configured to access database 132. Such data can be used to verify that request 160 is valid and is from a legitimate source.

The generated type change code 140 can include the serial number 141 of the engine control unit 120 and the type identifier 142. Other data may be contained within the retype code 140, which may be encrypted, scrambled, or modified to be readable only by the engine control unit 120. .. The type change code 140 may also be referred to as a "key" and may be used to "unlock" the configuration (parameters and calibration) at a position within the engine control unit 120, but corresponds to the type 121. May not be available due to having a mold that does not. The retyping code 140 can be provided in any way, such as by electrically passing through the internet 150, by language, by any kind of disc, or by any other means. There are ways to use, all of which are intended to be within the scope of this disclosure.

Upon receipt of the type change code 140, the operator of the engine 110 can bring the type change code 140 to the engine control unit 120 in one embodiment using the interface 122. The engine control unit 120 checks the type change code 140 (after decoding, if necessary) to ensure that the serial number 141 matches the serial number configured on the engine control unit 120. You may have and configure the software to do so. The type change is set by the engine control unit 120 at the time of receiving the type change code 140 or by the operator, or is specified by the type change code 140, according to bidirectional processing with the operator after receiving the type change code 140. It may be executed immediately by the engine control unit 120 at some time after this. All such embodiments are intended to be within the scope of this disclosure.

When the mold 121 is modified in the engine control unit 120 in response to the receipt of the mold change code 140, the operator is allowed to select the configuration, parameters, and calibration associated with the mold in the engine control unit 120. Can be done.

FIG. 2 shows an exemplary, non-limiting method 200 that implements an embodiment as disclosed herein. Method 200, and the individual actions and functions described in Method 200, can be performed by any one or more devices or components, which devices or components are the code generation server 130 of FIG. / Or includes the devices or components described herein, such as any other component or device of the system shown in FIG. In one embodiment, method 200 may be performed with any other device, component, or combination thereof, and in some embodiments, with other systems, devices, and / or components. Good. Any of the features and / or actions described for any of the blocks of Method 200, in any order, separately, of Method 200 or any of the other blocks of any other method described herein. It may be performed with a subset of other functions and / or actions described with respect to, and in combination with other functions and / or actions, the functions and actions described herein and mentioned herein. Note that it includes features and behaviors that are not. All such embodiments are intended to be within the scope of this disclosure.

At block 210, a request for type change can be received from the engine operator. This request may be encrypted. The request may include a serial number for the engine control unit and the desired type or identifier of the desired type, as well as any information that may be used. As mentioned, this request can be received in any way, such as electronically, linguistically, or via fax. At block 220, it is possible to determine whether the request is approved. For example, the serial number provided in the request can be compared to the stored serial number and cross-checked against the identification information for the engine operator. The request can also be decrypted at block 220 to ensure authenticity. In some embodiments, the particular type change requested is approved by, for example, an engineer or technician familiar with the relevant engine to ensure the technical and mechanical integrity of the requested change. , And / or it may be necessary to guarantee that the operator has paid for the requested type. If for some reason the request is not approved, at block 225, the requesting operator may receive a notification and no retype code may be generated.

If the request is approved, block 230 can generate a type change code. This code can include the serial number of the affected engine control unit and an identifier of the desired type. The code may also include arbitrary instructions and encrypted data that assist the engine control unit or direct the engine control unit to achieve the requested type change. The type change code can then be sent to the operator at block 240 using any means.

FIG. 3 shows an exemplary, non-limiting method 300 that implements one embodiment as disclosed herein. The method 300, and the individual actions and functions described in method 300, can be performed by any one or more devices or components, which are the engine control unit 120 of FIG. 1 and the engine control unit 120, and / Or includes the devices or components described herein, such as any other component or device of the system shown in FIG. In one embodiment, method 300 may be performed with any other device, component, or combination thereof, and in some embodiments, with other systems, devices, and / or components. Good. Any of the functions and / or operations described for any of the blocks of Method 300, separately in any order, is either Method 300 or any other block of any other method described herein. It may be performed with a subset of other functions and / or actions described with respect to, and in combination with other functions and / or actions, the functions and actions described herein and mentioned herein. Note that it includes features and behaviors that are not. All such embodiments are intended to be within the scope of this disclosure.

At block 310, the type change code as generated by method 200 of FIG. 2 can be received by the engine control unit. This type change code can include a time or time frame, serial number, and new type identifier to perform the type change, as well as any other data or instructions that cause the engine control unit to perform the type change. Can be included. At block 320, the received type change code can be verified. This may include decrypting the code, if desired. Other verifications may include determining if the serial number provided by the retype code corresponds to the serial number of the receiving engine control unit. If for some reason the retype code cannot be validated, at block 325 the operator may be notified and no retype may be performed.

If the time for type change is specified by the type change code or by the operator, at block 330, the engine control unit can determine if it is time to perform the change. This is because the response to receiving a manual instruction from the operator to start the type change at a specific time, or the type change code determines that the specified time for the type change is included and the type change. It may be a response to the judgment that it is not yet the time. If it was not the time for the type change, the engine control unit could continue to monitor the time and compare that time with the time or time frame provided to perform the type change. Stay in block 330. At block 340, the type change can be performed when it is time to perform the type change, or when the current time is within the time frame in which the type change is allowed to be performed. At block 350, the operator can be notified that the change has been made.

When a type change is made, any changes to the configuration of the engine control unit can be compared to the new type and ensure that it is compatible with the new type. The options for configuration changes in the engine control unit presented to the operator are also presented so that only those changes associated with the type currently configured in the engine control unit are presented and available for the operator to select. , Can be adjusted.

Calibration changes and other changes that are not retyped can also be controlled using the embodiments described herein. FIG. 4 shows an exemplary system 400 that can be implemented by one embodiment for changing calibration and other settings in the engine or engine control unit. Like the system 100 of FIG. 1, the illustrated system 400 is a simplified block diagram used to illustrate the concepts disclosed herein, and thus any embodiment disclosed herein. It should not be construed as describing any physical requirements or specific configurations required for. All components, devices, systems, and methods disclosed herein can be implemented in any number of components of any shape, form, or type, making it possible to implement the disclosed embodiments. Any combination of any such components is intended to be within the scope of this disclosure.

The engine 410 can be of any type of engine and includes any type of internal combustion engine, such as a gas turbine engine, a diesel engine, and a gasoline engine. The engine control unit 420 can be any type of computing device or control, can control any component of the engine 410 and the engine 410, and control and / or parameters that affect the operation of the engine 410. Or can be set. Modern engines can have many different parameters and calibrations that can be adjusted or set. These include maximum horsepower possible, maximum torque possible, maximum revolutions per minute (RPM) possible, maximum overload, time map, speed control adjustment, maximum boost to enable turbocharged engine, engine, There are engine calibration factors, as well as limits to engine fluid temperature, detonation limits, and the number of cylinders to use under certain conditions. All such parameters and calibrations, and any other parameters and calibrations that can be configured for the engine, are intended to be within the scope of the present disclosure. All parameters and calibrations can be initially set at the time of manufacture or before the engines using such engine control units are provided to the customer to ensure they are accurate. .. The engine control unit may be configured to prevent the customer from changing such parameters and calibrations without the assistance of the engine and / or the seller or manufacturer of the engine control unit. it can.

The engine control unit 420 may include an internal clock 421 that maintains the current time and / or may be used to track the operating time (ie, the amount of time the engine has operated). The engine control unit 420 may also have a serial number. The engine control unit may also be configured with an interface 422 that allows bidirectional processing with the engine control unit 420. Interface 422 includes any one or more such as keyboards, monitors, mice, disk drives, and network connections to any one or more networks (including the Internet, other data networks, and voice networks). It may be.

Determining that a calibration change is necessary, the engine 410 operator can send a request 460 requesting a calibration change code to adjust the calibration configured by the engine control unit 420. Request 460 can take any form, including a call in which the operator requests a calibration change code from the seller or manufacturer of the engine 410. Accordingly, the seller or manufacturer may generate and provide such code as described herein. Alternatively, the operator of engine 410 can use an automated interface such as a web page to generate request 460, and in some embodiments, automatically generated, generated as described herein. You can receive the calibration change code. In yet another embodiment, the operator emails or sends some other form of electronic request 460 for such code to the manufacturer or seller of engine 410 via the Internet 450. Can be received in the same way with a response containing the requested calibration change code that can be generated manually or automatically. All such embodiments are intended to be within the scope of this disclosure.

In one embodiment, request 460 from the operator can include the desired specific calibration and / or parameter change 463, plus serial number 461 of engine control unit 120 and operating time 162 of engine control unit 120. Can be included. Alternatively, request 460 may be a desired specific calibration and / or parameter change 463, serial number 461 of engine control unit 420, and future operating time relative to the starting time of operation of engine 410 or the current operating time of engine 410. It may include the time when the calibration is desired to be changed with respect to the reference time such as. Engine types can also be included and used, as illustrated with respect to FIGS. 1 to 3. In that case, this request may be made to the manufacturer or seller of the engine 410. Note that the request is also encrypted so that only the intended recipient can decrypt the request.

Instead of the serial number of the engine control unit 420, the request may include one or more identifiers that can be used by the manufacturer or seller of the engine 410 to determine the serial number for the engine control unit 420. Please note that. Such an identifier includes an engine type identifier that can be embedded in the software, firmware, and / or hardware used by the engine control unit 420 and further allows the identification of a particular type of engine 410. Can be done. Other alternative identifiers are identifiers for one or more circuit boards, motherboards, or any other type of hardware configured within the engine control unit 420, or a combination of such hardware. It can be an identifier to identify. Yet another alternative identifier, in some embodiments representing only well-performed calibration changes, while calibrating regardless of whether such a requirement corresponds to a well-performed calibration change. In other embodiments that represent the number of requests for change, it can be an identifier that represents the number of calibration changes that have been requested so far.

Upon receipt of the request, the manufacturer or seller of the engine 410 can validate the request, decode the request 460 if necessary, and generate a calibration change code 440. In some embodiments, the requested changes may have been indicated in the request or determined from other sources as described above to ensure that the changes are compatible with the engine type. It can be compared with the engine type of the engine 410. In one embodiment, a calibration server 430 may be used to generate such code. The calibration server 430 can be any type of computing device, or any number and any combination of types of computing devices. The calibration server 430 can be configured with an internal clock 431 that can be used to adjust and / or synchronize the time included in the request, such as request 460, thereby the calibration change code 440. Is accepted by the engine control unit. The calibration server 430 is also configured with a serial number, operation start time (used to determine the current operation time), and any other data associated with the engine and engine control unit. It can be configured with database 432, which can be a database, or it can be configured to access database 432. Such data can be used to verify that request 460 is valid and comes from a legitimate source.

The generated calibration change code 440 can be the serial number 441 of the engine control unit 420, the operating time 442 which can be the operating time during which changes to the calibration of the engine control unit 420 may have been made, and the engine 410. A calibration 443 can be included, which can be a calibration or modification of one or more to the parameters of the engine control unit 420, as required by the operator of. It should be noted that the operating time 442 can be a single time in the future or a time frame in which the change is made. For example, if the operating time 442 is a single time, the changes brought about by calibration 443 may be made automatically by the engine control unit 420 at that time. Alternatively, if the operating time 442 is a time frame, the changes brought about by calibration 443 may be made only during that time frame. The calibration change code 440 can be encrypted and can be provided in any way, such as by electrical means through the internet 450, by language, by any kind of disk. There are methods, or methods using any other means, all of which are intended to be within the scope of this disclosure. The engine type can also be included in the calibration code and can be used as described above with respect to FIGS. 1 to 3.

Upon receiving the calibration change code 440, the operator of the engine 410 can bring the calibration change code 440 to the engine control unit 420 in one embodiment using the interface 422. The engine control unit 420 checks the calibration change code 440 (after decoding, if necessary) to ensure that the serial number 441 matches the serial number configured on the engine control unit 420. It may be configured with software to be used. In that case, the software can determine whether the operating time 442 is present, past, or has not yet been reached. If the operating time 442 is in the past, the engine control unit 420 may reject the calibration change code 440 or may not make the changes brought about by the calibration 443. If the operating time 442 is current or is in a time frame that includes the current time, the engine control unit 420 can make the changes brought about by the calibration change code 440. If the operating time 442 is a future time or a future time frame, the engine control unit 420 waits to make the changes brought about by the calibration change code 440 until the future time or time frame is reached. Can be done.

Alternatively, the operator of the engine 410 may use the interface 422 to manually instruct the engine control unit 420 to make the changes brought about by the calibration change code 440. Upon receiving such an instruction, the engine control unit 420 can verify that the instruction was received within the time frame or time provided by the operating time 442, and if so, implement the change. Can be done. If such an instruction is received outside the time provided by the operating time 442, the engine control unit 420 may not make the change and will give the operator an error message indicating that the change was not made. be able to.

FIG. 5 shows an exemplary, non-limiting method 500 that implements one embodiment as disclosed herein. Method 500, and the individual actions and functions described in Method 500, can be performed by any one or more devices or components, which devices or components are the code generation server 130 of FIG. 1, FIG. Includes the devices or components described herein, such as the calibration server 430 of 4 and / or any other component or device of the system shown in FIGS. 1 and 4. In one embodiment, method 500 may be performed with any other device, component, or combination thereof, and in some embodiments, with other systems, devices, and / or components. Good. Any of the functions and / or operations described for any of the blocks of Method 500, separately in any order, is either Method 500 or any other block of any other method described herein. It may be performed with a subset of other functions and / or actions described with respect to, and in combination with other functions and / or actions, the functions and actions described herein and mentioned herein. Note that it includes features and behaviors that are not. All such embodiments are intended to be within the scope of this disclosure.

At block 510, a request for a calibration change can be received from the engine operator. This request may be encrypted. This request can include a serial number for the engine control unit, a time or time frame to start the change, any desired change, engine type, and any other information that may be used. As mentioned, this request can be received in any way, such as electronically, linguistically, or via fax. At block 520, it is possible to determine whether the request is approved. For example, the serial number provided by the request can be compared to the stored serial number and cross-checked against the identification information for the engine operator. Alternatively, the engine type of the engine associated with the engine control unit to be changed may be checked to ensure that the requested changes match the engine type. The request can also be decrypted to ensure authenticity at block 520. In some embodiments, the particular changes requested are approved, for example, by an engineer or technician familiar with the relevant engine to ensure the technical and mechanical integrity of the changes requested. May be required. If for some reason the request is not approved, at block 525, the requesting operator may be notified and no calibration change code may be generated.

If the request is approved, block 530 can generate a calibration change code. This code includes the serial number of the affected engine control unit, the time or time frame to start the change, and the specific code, instruction, engine type, etc. that tells the engine control unit to make the requested change. be able to. The calibration change code can then be sent to the operator at block 540.

FIG. 6 shows an exemplary, non-limiting method 600 that implements one embodiment as disclosed herein. Method 600, and the individual actions and functions described in Method 600, can be performed by any one or more devices or components, the devices or components of which are engine control unit 120 of FIG. 1, FIG. Includes the devices or components described herein, such as the engine control unit 420 of 4, and / or any other component or device of the system shown in FIGS. 1 and 4. In one embodiment, method 600 may be performed with any other device, component, or combination thereof, and in some embodiments, with other systems, devices, and / or components. Good. Any of the functions and / or operations described for any of the blocks of Method 600, separately in any order, is either Method 600 or any other block of any other method described herein. It may be performed with a subset of other functions and / or actions described with respect to, and in combination with other functions and / or actions, the functions and actions described herein and mentioned herein. Note that it includes features and behaviors that are not. All such embodiments are intended to be within the scope of this disclosure.

At block 610, the calibration change code as generated by method 500 of FIG. 5 can be received by the engine control unit. This calibration change code gives one or more codes or instructions that force the time or time frame, serial number, engine type, and engine control unit to perform the change to perform the calibration and / or the change to the parameters. Can include. At block 620, the received calibration change code can be verified. This may include decrypting the code, if desired. Other verifications include determining that the serial number provided by the calibration change code corresponds to the serial number of the receiving engine control unit and that the time or time frame for the change is not in the past. It may be. If for some reason the calibration change code cannot be verified, at block 625 the operator may be notified and no changes may be made.

At block 630, the engine control unit can determine if the time to implement the change has been reached. This is in response to receiving a manual instruction from the operator to perform the enumerated changes, or to receiving a change code and preliminarily determining that it is not yet time for the change. It may be a response. If it was not the time for the change, the engine control unit could continue to monitor the time and compare that time with the time or time frame brought to make the change, block 630. Stay in. If it is time to make the change, or if the current time is within the time frame in which the change is allowed to be made, the change can be made at block 640. At block 650, the operator can be notified that the change has been made.

The technical effects of the systems and methods described herein are to control changes to the engine type calibrated by the engine control unit and to ensure that only changes that match the permitted engine type are performed. Ability. A further technical effect of the systems and methods described herein is the ability to control changes to the engine and engine control units to ensure efficiency and performance. The systems and methods described herein can facilitate such engine operators to request and implement changes in engine type and engine control units. As will be appreciated by those skilled in the art, the disclosed processing and use of the system can increase operator flexibility while maintaining engine reliability and efficient operation. Those skilled in the art will recognize that the disclosed systems and methods can be combined with other systems and technologies to achieve greater benefits. All such embodiments are intended to be within the scope of this disclosure.

In some embodiments, the changes can be made larger than would be readily made using a type change code or calibration code as described herein, in such embodiments. , The type change code or calibration code, or instead, the engine control unit, such as change instructions and / or updated software or firmware (for type changes, calibration changes, or other changes). Note that it can be made possible to download or receive via a network connection. Any code, typing, calibration, and other adjustments can be made to the engine by allowing the engine control unit to communicate with remote devices using retype codes as described herein. Can be made available in the control unit. All such embodiments are intended to be within the scope of this disclosure.

FIG. 7 and the following description provide a concise and general description of the appropriate computing environment in which the engine control unit configuration security systems and methods and / or parts thereof disclosed herein can be implemented. Intended to provide. For example, the functions of engine control units 120 and 420, code generation server 130, and calibration server 430 can be performed by one or more devices that include some or all of the embodiments described with respect to FIG. Some or all of the devices described in FIG. 7, which can be used to perform the functions of the claimed embodiment, can be embedded in a system such as those described with respect to FIGS. 1 and 4. Can be configured within. Alternatively, some or all of the devices described in FIG. 7 may be included in any device, combination of devices, or any system that implements any aspect of the disclosed embodiments.

Although not necessarily required, the engine control unit configuration security systems and methods disclosed herein are common for computer-executable instructions, such as program modules, executed by a computer, such as a client workstation, server, or personal computer. Can be explained in various contexts. Such computer-executable instructions can be stored in any type of computer-readable storage device, not the transient signal itself. In general, a program module includes routines, programs, objects, components, data structures, etc. that perform a particular task or implement a particular abstract data type. In addition, the engine control unit configuration security systems and methods and / or parts thereof described herein can be implemented with other computer system configurations, such other computer system configurations include handheld devices. It should be recognized that it includes multiprocessor systems, microprocessor or programmable consumer electronics, network PCs, minicomputers, and mainframe computers. The methods and systems disclosed herein may also be implemented in a distributed computing environment in which tasks are performed by remote processing devices linked over a communication network. In a distributed computing environment, program modules may be located in both local and remote memory storage devices.

FIG. 7 is a block diagram representing a general purpose computer system in which the methods and / or some aspects thereof disclosed herein can be incorporated. As shown in the figure, an exemplary general purpose computing system includes a computer 720 and the like, in which the computer 720 connects a processing unit 721, a system memory 722, and various system components including the system memory to the processing unit 721. including. The system bus 723 can be of any type of bus structure, including a memory bus or memory controller, a peripheral bus, and a local bus that uses any of the various bus architectures. The system memory may include read-only memory (ROM) 724 and random access memory (RAM) 725. The basic input / output system 726 (BIOS) can include a basic routine that assists in transferring information between elements in the computer 720, such as during startup, and can be stored in the ROM 724.

The computer 720 includes a hard disk drive 727 for reading and writing to a hard disk (not shown), a magnetic disk drive 728 for reading and writing to a removable magnetic disk 729, and / or a removable optical disk 731 such as a CD-ROM or other optical media. An optical disk drive 730 for reading and writing may be further provided. The hard disk drive 727, the magnetic disk drive 728, and the optical disk drive 730 can be connected to the system bus 723 by the hard disk drive interface 732, the magnetic disk drive interface 733, and the optical drive interface 734, respectively. The drive and associated machine-readable media provide non-volatile storage of computer-readable instructions, data structures, program modules, and other data for the computer 720.

The exemplary environment described herein uses a hard disk, a removable magnetic disk 729, and a removable optical disk 731, but other types of computer reads that can store data accessible by a computer are also exemplified. It should be recognized that it can be used in a removable operating environment. Such other types of media include, but are not limited to, magnetic cassettes, flash memory cards, digital video or versatile discs, Bernoulli cartridges, random access memory (RAM), and read-only memory ( ROM) and so on.

Many program modules can be stored on the hard disk drive 727, magnetic disk 729, optical disk 731, ROM 724, and / or RAM 725, such program modules as operating system 735, one or more application programs. There are 736, other program modules 737, and program data 738. The user can enter commands and information into the computer 720 via input devices such as the keyboard 740 and the pointing device 742. Other input devices (not shown) can include microphones, joysticks, gamepads, satellite discs, scanners, and the like. These and other input devices are often connected to the processing unit 721 via a serial port interface 746 coupled to the system bus, such as a parallel port, game port, or universal serial bus (USB). It may be connected by another interface. A monitor 747 or other type of display device can also be connected to the system bus 723 via an interface such as a video adapter 748. In addition to monitor 747, the computer may include other peripheral output devices (not shown) such as speakers and printers. The exemplary system of FIG. 7 can also include a host adapter 755, a Small Computer System Interface (SCSI) bus 756, and an external storage device 762 that can be connected to the SCSI bus 756.

Computer 720 operates in a network environment using logical and / or physical connections to one or more remote computers or devices, such as remote computer 749, components of engine 110, and engine control unit 120. be able to. The components of the engine 110 and the engine control unit 120 can perform the functions described and can be any device as described herein. The remote computer 749 can be a personal computer, server, router, network PC, peer device, or other common network node and may include many or all of the above-mentioned elements with respect to the computer 720, but the memory storage device 750. Only are shown in FIG. The logical connection shown in FIG. 7 may include a local area network (LAN) 751 and a wide area network (WAN) 752. Such networking environments are common in offices, enterprise-scale computer networks, intranets, and the Internet.

When used in a LAN networking environment, the computer 720 can be connected to the LAN 751 via a network interface or adapter 753. When used in a WAN networking environment, the computer 720 can include a modem 754, or other means of establishing communication over a wide area network 752 such as the Internet. The modem 754 can be internal or external and can be connected to the system bus 723 via the serial port interface 746. In a network environment, the program modules shown in relation to the computer 720, or a portion thereof, can be stored in a remote memory storage device. It will be appreciated that the network connections shown are exemplary and other means of establishing communication links between computers may be used.

Computer 720 can include a variety of computer readable storage media. Computer-readable storage media may be any available, tangible, non-transitory, or non-propagating media, including volatile and non-volatile media, removable and non-removable media, accessible to computer 720. be able to. For example, but not limited to, computer readable media can include computer storage media and communication media. Computer storage media are volatile and non-volatile, removable and non-removable, implemented by any method or technique for storing information such as computer-readable instructions, data structures, program modules, or other data. Including media. Computer storage media are, but are not limited to, RAM, ROM, EEPROM, flash memory or other memory technology, CD-ROM, digital versatile disc (DVD) or other optical disc storage, magnetic cassette, magnetic tape. Includes magnetic disk storage or other magnetic storage devices, or any other tangible media that can be used to store desired information and can be accessed by computer 720. Any combination of the above is also included within the scope of computer readable media that can be used to store the source code for implementing the methods and systems described herein. Any combination of features or elements disclosed herein can be used in one or more embodiments.

The present specification includes any device or system to disclose the subject matter of the invention contained herein, including the best form, and any device or system, including making and using, and performing any embedding method. Examples are used to allow one of ordinary skill in the art to carry out the present invention. The patentable scope of the present disclosure is defined by the claims and may include other examples conceived by those skilled in the art. Such other embodiments are patented if they have structural elements that are not significantly different from the wording of the claims, or if they contain equivalent structural elements that are not substantially different from the wording of the claims. It is within the claims.

100 System 110 Engine 120 Engine Control Unit 121 Type 122 Interface 130 Code Generation Server 132 Database 140 Type Change Code 141 Serial Number 142 Type Identifier 150 Internet 160 Request 161 Serial Number 162 Identifier 200 Method 210 Block 220 Block 225 Block 230 Block 240 Block 300 Method 310 Block 320 Block 325 Block 330 Block 340 Block 350 Block 420 Computer 400 System 410 Engine 420 Engine Control Unit 421 Internal Clock 430 Calibration Server 431 Internal Clock 432 Database 440 Calibration Change Code 441 Serial Number 442 Operating Time 443 Calibration 450 Internet 460 Request 461 Serial Number 462 Change Time 463 Parameter Change 500 Method 510 Block 520 Block 525 Block 530 Block 540 Block 600 Method 610 Block 620 Block 625 Block 630 Block 640 Block 650 Block 720 Computer 721 Processing Unit 722 Memory 723 Bus 724 ROM
725 RAM
726 BIOS (basic input / output system)
727 Hard Disk Drive 728 Magnetic Disk Drive 729 Removable Magnetic Disk 730 Optical Disk Drive 731 Removable Optical Disk 732 Hard Drive Interface 733 Magnetic Disk Drive Interface 734 Optical Disk Drive Interface 735 Operating System 736 Application Program 737 Program Module 738 Program Data 740 Keyboard 742 Pointing Device 746 Serial Port Interface 747 Monitor 748 Video Adapter 749 Remote Computer 750 Memory Storage Device 751 LAN
752 WAN
753 Adapter 754 Modem 755 Host Adapter 756 SCSI Bus 762 External Storage Device

Claims (10)

The system (100) includes a memory (722) for storing a program and a processor (721) connected to the memory (722).
The program is supplied to the processor (721).
The change control device (130, 430) receives the serial number (161, 461) associated with the engine control unit (120, 420) and the required engine control unit change (162, 463).
The required engine control unit change (162, 463) is approved to ensure that the serial number (161, 461) associated with the engine control unit (120, 420) matches the corresponding serial number. To judge what was done,
To generate a code (140, 440) with the serial number (141, 441) associated with the engine control unit (120, 420), and to the engine control unit (120, 420).
The required engine control unit changes (162, 463) are carried out.
Reject the code or
Do not implement the required engine control unit changes (162, 463).
Generating instructions (143, 443),
To run,
Determining that the requested engine control unit change (162, 463) has been approved means that the operator of the engine (110, 410) associated with the engine control unit (120, 420) is required. Bei example to determine that it has pay for that engine control unit changes (162,463),
The required engine control unit change (162, 463) is a calibration change composed of the engine control unit (120, 420) and an engine type change composed of the engine control unit (120, 420). On the other hand,
A system (100) that protects the configuration of the engine control unit. Further comprising receiving a change time (462), the system of <br/> claim 1. The serial number (161, 461) associated with the engine control unit (120, 420) and the required engine control unit change (162, 463) are received in an encrypted electronic message, claim. The system according to either 1 or 2. The system according to any one of claims 1 to 3 , further comprising transmitting the code to the engine control unit (120, 420) in an encrypted electronic message. Determining that the required engine control unit change (162, 463) has been approved means that the engine (110, 410) associated with the engine control unit (120, 420) is the engine required. The system according to any one of claims 1 to 4 , comprising determining that the control unit modification (162, 463) is compatible. A step of receiving the serial number (161, 461) associated with the engine control unit (120, 420) and the required engine control unit change (162, 463) on the change control device (130, 430).
A step of confirming that the serial number (161, 461) associated with the engine control unit (120, 420) matches the corresponding serial number, and
A step of determining that the required engine control unit change (162, 463) has been approved by the change control device (130, 430).
A step of generating a code with the serial number (161, 461) associated with the engine control unit (120, 420) at the change control device (130, 430), and the engine control unit (120, 420). To,
The required engine control unit changes (162, 463) are carried out.
Reject the code or
Do not implement the required engine control unit changes (162, 463).
Steps to generate instructions and
Including
The step of determining that the requested engine control unit change (162, 463) has been approved is such that the operator of the engine (110, 410) associated with the engine control unit (120, 420) is requested. Bei example the step of determining that the pay for that engine control unit changes (162,463),
The required engine control unit change (162, 463) is a calibration change composed of the engine control unit (120, 420) and an engine type change composed of the engine control unit (120, 420). On the other hand,
A method for protecting the configuration of the engine control unit. The method of claim 6 , further comprising the step of receiving a change time (462). The serial number (161, 461) associated with the engine control unit (120, 420) and the required engine control unit change (162, 463) are received in an encrypted electronic message, claim. The method according to any one of 6 or 7. The method according to any one of claims 6 to 8 , further comprising a step of transmitting the code to the engine control unit (120, 420) in an encrypted electronic message. The step of determining that the required engine control unit change (162, 463) has been approved is that the engine (110, 410) associated with the engine control unit (120, 420) is the engine required. comprising the step of determining that it is compatible with the control unit changes (162,463) the method of any of claims 6-9.